CN103175314A - Solar vacuum glass heat collecting tube air heat collector - Google Patents
Solar vacuum glass heat collecting tube air heat collector Download PDFInfo
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- CN103175314A CN103175314A CN2013100898477A CN201310089847A CN103175314A CN 103175314 A CN103175314 A CN 103175314A CN 2013100898477 A CN2013100898477 A CN 2013100898477A CN 201310089847 A CN201310089847 A CN 201310089847A CN 103175314 A CN103175314 A CN 103175314A
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S10/00—Solar heat collectors using working fluids
- F24S10/40—Solar heat collectors using working fluids in absorbing elements surrounded by transparent enclosures, e.g. evacuated solar collectors
- F24S10/45—Solar heat collectors using working fluids in absorbing elements surrounded by transparent enclosures, e.g. evacuated solar collectors the enclosure being cylindrical
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S10/00—Solar heat collectors using working fluids
- F24S10/70—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits
- F24S10/75—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits with enlarged surfaces, e.g. with protrusions or corrugations
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/44—Heat exchange systems
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- Thermal Sciences (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
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Abstract
The invention provides a solar vacuum glass heat collecting tube air heat collector, belongs to the field of solar air heating equipment, and particularly relates to a device which uses a solar vacuum glass heat collecting tube and a metal thermal tube which are combined for air heating and heat collecting. The solar vacuum glass heat collecting tube air heat collector is characterized in that a fan radiator (10) is arranged inside an air heat collecting chamber (9), the air heat collecting chamber (9) is connected with a condensing end at the top end of the metal thermal tube (4) through the fin radiator (10), and radiating fins (11) which are distributed in a radiating shape mode are arranged on the outer peripheral ring of the fin radiator (10). The solar vacuum glass heat collecting tube air heat collector has the advantages of being high in heat transmission speed, high in solar heat energy utilization ratio, good in sealing effect and the like.
Description
Technical field
A kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector belongs to solar air firing equipment field, is specifically related to a kind of device that utilizes solar energy vacuum glass thermal-collecting tube and metal heat pipe to be incorporated into line space gas heating thermal-arrest.
Background technology
Along with the continuous increase of the day by day in short supply and environmental protection pressure of coal, oil equal energy source, each state all begins to try hard to recommend regenerative resource, and wherein, development and utilization solar energy becomes new lover the most hot in regenerative resource, develops and utilizes solar energy to become trend of the times.At first, solar energy optical-thermal has developed for many years in China, but great majority all concentrate on solar water and use the field, a little less than the technological development relative thin of solar energy hot blast aspect, be not effectively utilized, and the solar heat wind system is no matter have more significantly advantage at aspects such as cost, technical stability, solar thermal utilization rates; Secondly, the most forms that adopt hot-water heating, hot air heating or new air heat-exchange of at present domestic indoor heating, and hot-water heating and hot air heating are still the mode of fuel such as adopting electrical heating or coal, waste oil and produce, not environmental protection, new air heat-exchange need to utilize electric energy to heat realization equally, therefore, above heat-supplying mode is quite serious to the waste of the energy.
Adopt glass tube to carry out thermal-arrest though existing solar energy air heat-collecting device also has, but due to the restriction of self structure, mostly have the problems such as heat transfer rate is slow, efficient is low, the large weak effect of duct resistance.
Summary of the invention
The technical problem to be solved in the present invention is: overcome the deficiencies in the prior art, provide that a kind of heat transfer rate is fast, the solar energy utilization rate is high, the solar energy vacuum glass thermal-collecting tube heat pipe air heat collector of good sealing effect.
the technical solution adopted for the present invention to solve the technical problems is: this kind solar energy vacuum glass thermal-collecting tube heat pipe air heat collector, comprise a plurality of vacuum glass heat collection tubes that are arranged side by side and air heat-collecting chamber, the air heat-collecting chamber is connected as a single entity a plurality of vacuum glass heat collection tubes tops, metal heat pipe is installed in vacuum glass heat collection tube, the metal heat pipe top is condensation end, the bottom is evaporator section, evaporator section stretches in vacuum glass heat collection tube, condensation end stretches in the air heat-collecting chamber, be installed with the thermal-arrest fin on the outer ring tube wall of metal heat pipe evaporator section, it is characterized in that: the indoor fin radiator that is provided with of described air heat-collecting, condensation end by fin radiator connection metal heat pipe top, border, the fin radiator outside is provided with radial heat-dissipating fin of arranging.By the thermal-arrest fin, the heat that canals of stilling absorbs is passed to metal heat pipe, phase-change material is vaporized at the evaporator section absorption heat of metal heat pipe, rising to condensation end is condensed into liquid and emits heat, be back to again evaporator section, continue to absorb heat, absorption efficiency is high, and the reverse heat radiation when having avoided without solar radiation.
Described air heat-collecting chamber comprises fin radiator and the heat-dissipating fin of installing in shell, inner bag, inner bag, is provided with heat-insulation layer between shell and inner bag, and heat-dissipating fin is along fin radiator tube axon to being the radial fin radiator outer ring of being distributed on; Shell one end is provided with air inlet, and the other end is provided with the gas outlet, and the air inlet place is provided with air filter and opens and closes reversing arrangement, and the place, gas outlet is provided with headstock gear.
Described fin radiator is installed in parallel in inner bag, the fin radiator is the body of inner hollow, the body both ends are provided with plug, body internal circulation heat accumulation heat-conducting medium, body one end is provided with the medium filler pipe, medium filler pipe one end stretches out the air heat-collecting chamber as the medium filler, and is provided with pressure relief device; Be provided with side by side a plurality of heat transfer sleeve pipes in the fin radiator, the condensation end at metal heat pipe top exposes the vacuum glass heat collection tube top and inserts in the heat transfer sleeve pipe.The systemic heat of vacuum glass heat collection tube is delivered in the indoor fin radiator of air heat-collecting by metal heat pipe, and the air by the heat-dissipating fin on the fin radiator and the indoor circulation of air heat-collecting carries out heat exchange; The mode that the heat transfer sleeve pipe adopts soldering or screw to connect is bumped in fin radiator tube chamber, so that the installation of metal heat pipe is fixed.
The described vacuum glass heat collection tube that metal heat pipe is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are arranged on the same side of air heat-collecting chamber side by side, and the bottom of vacuum glass heat collection tube is fixedly mounted on framework and links into an integrated entity by framework and air heat-collecting chamber.
The described vacuum glass heat collection tube that metal heat pipe is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are divided into two groups, symmetrical both sides that are arranged on the air heat-collecting chamber side by side, the bottom of two groups of vacuum glass heat collection tubes are fixedly mounted on framework and link into an integrated entity by framework and air heat-collecting chamber.
Described fin radiator is installed in parallel in inner bag, the fin radiator is the body of inner hollow, body two ends or side, two ends are connected by flow-path tube, in the fin radiator and flow-path tube internal circulation heat accumulation heat-conducting medium, flow-path tube one end is provided with the medium filler pipe, medium filler pipe one end stretches out the air heat-collecting chamber as the medium filler, and is provided with pressure relief device; Be provided with side by side a plurality of heat transfer sleeve pipes on flow-path tube, the condensation end at metal heat pipe top exposes the vacuum glass heat collection tube top and inserts in the heat transfer sleeve pipe.Heat accumulation heat-conducting medium in the fin radiator and the heat accumulation heat-conducting medium convection heat transfer' heat-transfer by convection in flow-path tube, the condensation end at metal heat pipe top passes to the fin radiator with heat by the heat accumulation heat-conducting medium in flow-path tube, and outdoor air enters the heat-dissipating fin generation heat exchange of installing on air heat-collecting chamber and fin radiator and fin radiator outer ring.
The described vacuum glass heat collection tube that metal heat pipe is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are arranged on the same side of air heat-collecting chamber side by side, and the bottom of vacuum glass heat collection tube is fixedly mounted on framework and links into an integrated entity by framework and air heat-collecting chamber.
The described vacuum glass heat collection tube that metal heat pipe is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are divided into two groups, flow-path tube is arranged with two sections, two groups of vacuum glass heat collection tube symmetries are arranged on both sides, air heat-collecting chamber, two groups of corresponding metal heat pipes by two sections flow-path tubes side by side symmetry be arranged on both sides, air heat-collecting chamber, two groups of vacuum glass heat collection tubes bottoms are fixedly mounted on framework and link into an integrated entity by framework and air heat-collecting chamber.
Described air heat-collecting indoor horizontal arranges dividing plate, and dividing plate is arranged between fin radiator and flow-path tube, dividing plate top formation air communication channel.To reduce air at the indoor resistance of air heat-collecting.
Described fin radiator integral longitudinal section is circular, oval, semicircle, fan-shaped, trapezoidal, rhombus or rectangle, and the fin radiator is one piece machine-shaping or is formed by the body outer ring that a plurality of heat-dissipating fins that are processed into separately are plugged on the fin radiator.Fin radiator and heat-dissipating fin thereof can adopt aluminium alloy or stainless steel directly to push, cast the processing one-shot forming, also can be made into independent fin is arranged on pipe in the fin radiator by grafting the patching in groove of outer ring, heat-dissipating fin can be wide fin, also can form by the fin of different in width required shape.
Compared with prior art, the beneficial effect that has of the present invention is:
1, heat transfer rate is fast, efficient is high: utilize in glass tube with vacuum and glass tube metal heat pipe and with the thermal-arrest fin of curved surface, solar energy is carried out thermal-arrest, and the characteristic by the heat conduction with phase change in metal heat pipe, form unidirectional heat transfer, avoided the reverse heat radiation without solar radiation the time, high to the utilization rate of solar energy;
2, reliable, the good heat insulation of sealing, heat exchange fully, without water clock: adopt mechanical sealing, sealing-plug to add sealing ring and can guarantee sealing effectiveness fully, enough heat-insulation layer design and sealing effectiveness have guaranteed the thermal efficiency, large-area heat-dissipating fin and can be on heat-dissipating fin vertical fin-separating design of setting up, enough heat transfer effects and temperature have been guaranteed, do not have again simultaneously weeping to occur, there is no water and other media in the vacuum glass body, even if glass tube with vacuum damages, can not cause water clock yet;
3, applied widely, security and stability is high: heat transfer element adopts metal tube and metal foil fin, has good lower temperature resistance, can not lose efficacy under subzero 45 degree low-temperature conditions yet, adapting to each area uses, simultaneously under the condition of high temperature (as air drying time), there is not the hidden danger of booster in the heat transfer original paper yet;
4, adopt respectively ripe ready-made universal technology, not only make the consistent of product, also can drop to cost of manufacture minimum.
Description of drawings
Fig. 1 is solar energy vacuum glass thermal-collecting tube heat pipe air heat collector embodiment 1 front view cross-sectional schematic.
Fig. 2 is solar energy vacuum glass thermal-collecting tube heat pipe air heat collector embodiment 2 front view cross-sectional schematic.
Fig. 3 is solar energy vacuum glass thermal-collecting tube heat pipe air heat collector embodiment 3 front view cross-sectional schematic.
Fig. 4 is solar energy vacuum glass thermal-collecting tube heat pipe air heat collector embodiment 4 front view cross-sectional schematic.
Fig. 5 is that the longitudinal section is the side view schematic diagram of the fin radiator of circle.
Fig. 6 is that the longitudinal section is the side view schematic diagram of the fin radiator of rectangle.
Wherein: 1, framework 2, vacuum glass body 3, thermal-arrest fin 4, metal heat pipe 5, sealing-plug 6, sealing ring 7, air inlet 8, air filter 9, air heat-collecting chamber 10, fin radiator 11, heat-dissipating fin 12, gas outlet 13, headstock gear 14, temperature transducer 15, plug 16, flow-path tube 17, heat-insulation layer 18, shell 19, inner bag 20, medium filler pipe 21, heat transfer sleeve pipe.
The specific embodiment
Fig. 1 is most preferred embodiment of the present invention, and the present invention will be further described below in conjunction with accompanying drawing 1 ~ 6.
With reference to accompanying drawing 1: this a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector comprises framework 1, vacuum glass heat collection tube, metal heat pipe 4, sealing-plug 5, sealing ring 6, air filter 8, air heat-collecting chamber 9, fin radiator 10 and headstock gear 13.Air heat-collecting chamber 9 is the housing of rectangle, be arranged on the top of vacuum glass heat collection tube, 9 inside, air heat-collecting chamber are stretched on vacuum glass heat collection tube top, the bottom of vacuum glass heat collection tube is installed fixing by framework 1, and connects as one by being provided with air heat-collecting chamber 9 installing hole that vacuum glass heat collection tube is installed on framework 1.9 longitudinal sections, air heat-collecting chamber can be circular, semicircle, oval, fan-shaped, rectangle or rhombus.The whole longitudinal section of fin radiator 10 is circular, oval, semicircle, fan-shaped, trapezoidal, rhombus or rectangle.
air heat-collecting chamber 9 is horizontally disposed with, comprise shell 18, inner bag 19, the inner fin radiator of installing 10 of inner bag 19 and the heat-dissipating fin 11 that is arranged on fin radiator 10 outer borders, shell 18 adopts aluminium sheet, color steel, the material such as aluminium plating zinc plate or corrosion resistant plate is made, inner bag 19 adopts galvanized sheet, corrosion resistant plate or aluminium sheet are made, be provided with heat-insulation layer 17 between shell 18 and inner bag 19, shell 18 1 ends are provided with air inlet 7, the other end is provided with gas outlet 12, air inlet 7 places are provided with and open and close reversing arrangement and air filter 8, 12 places, gas outlet are provided with headstock gear 13, be provided with temperature transducer 14 on the shell 18 above air inlet 7.
Vacuum glass heat collection tube comprises hard-wired thermal-arrest fin 3 on sealing-plug 5 that vacuum glass body 2, vacuum glass body 2 tops of bottom lock are used for sealing and sealing ring 6, the inner metal heat pipe 4 of installing of body and metal heat pipe 4 tube walls.Vacuum glass heat collection tube is provided with a plurality of, a plurality of vacuum glass heat collection tubes are arranged on the same side of air heat-collecting chamber 9 side by side, a plurality of vacuum glass heat collection tubes top connects as one by air heat-collecting chamber 9, metal heat pipe 4 is the copper pipe of hollow, and the closed at both ends setting also vacuumizes, and phase-change material is housed in body, the body top is condensation end, the bottom is evaporator section, and condensation end exposes sealing-plug 5, and evaporator section stretches into vacuum glass heat collection tube inside.Thermal-arrest fin 3 is provided with one or more along metal heat pipe 4 tube wall vertical directions, be arranged in parallel between adjacent two thermal-arrest fins 3, thermal-arrest fin 3 cross sections are the curved surface setting, the two edges of curved surface and vacuum glass body 2 inwall close contacts, and thermal-arrest fin 3 is made for aluminium flake.
the course of work is as follows: this solar energy vacuum glass thermal-collecting tube heat pipe air heat collector is when work, absorb the heat energy of solar radiation by vacuum glass body 2, then by the thermal-arrest fin 3 that is fixedly mounted on metal heat pipe 4, heat is conducted to metal heat pipe 4, phase-change material in metal heat pipe 4, as a small amount of water etc., be heated and vaporize, the saturated vapor of having vaporized carries heat and rises to the condensation end at metal heat pipe 4 tops and flow, rise to rapidly condensation end, saturated vapor is emitted heat in the condensation end condensation, saturated vapor is condensed into liquid after emitting the latent heat of vaporization, the condensed fluid that forms is back to the evaporator section of metal heat pipe 4 bottoms under Action of Gravity Field, continue the heat absorption vaporization.and the heat that condensation end discharges passes to fin radiator 10, heat accumulation heat-conducting medium generation heat exchange with fin radiator 10 body inside, the heat of fin radiator 10 inside passes to heat-dissipating fin 11, again by heat-dissipating fin 11 distribute heats, simultaneously, outdoor air enters 9 inside, air heat-collecting chamber from the filtration of air inlet 7 process air filters 8, air and heat-dissipating fin 11 and the 10 body generation heat exchange of fin radiator of circulation, formation is with the warm braw of temperature, warm braw is discharged from the gas outlet 12 of air heat-collecting chamber 9 other ends, be supplied in the occasion of using warm braw.Air inlet 7 is controlled air switching by the keying transfer and is originated, and the opening and closing at 12 places, gas outlet are controlled by headstock gear 13.
With reference to accompanying drawing 2: vacuum glass heat collection tube is provided with a plurality of, a plurality of vacuum glass heat collection tubes are arranged on the same side of air heat-collecting chamber 9 side by side, the side at fin radiator 10 two ends or two ends is connected with flow-path tube 16 by connectors such as union elbow, three-way pipes, metal heat pipe 4 top condensation ends insert in the heat transfer sleeve pipe 21 that is arranged side by side on flow-path tube 16, flow-path tube 16 1 sides extensions are provided with medium filler pipe 20, medium filler pipe 20 1 ends stretch out air heat-collecting chamber 9 as the medium filler, and are provided with pressure relief device.The heat of a plurality of metal heat pipe 4 top condensation ends passes to fin radiator 10 in air heat-collecting chamber 9 by the heat accumulation heat-conducting medium in flow-path tube 16.Give by medium filler pipe 20 the heat accumulation heat-conducting medium of annotating in the inner and flow-path tube 16 of the body of fin radiator 10.Other settings are identical with embodiment 1.
Also can be horizontally disposed with a dividing plate in air heat-collecting chamber 9, dividing plate is arranged between fin radiator 10 and flow-path tube 16, by dividing plate, fin radiator 10 is isolated in the space of formation, dividing plate top formation air communication channel, fin radiator 10 horizontal centers are installed.
Embodiment
With reference to accompanying drawing 3: vacuum glass heat collection tube is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are divided into two groups, symmetrical both sides that are arranged on air heat-collecting chamber 9 side by side, the bottom of two groups of vacuum glass heat collection tubes are fixedly mounted on framework 1 and link into an integrated entity by framework 1 and air heat-collecting chamber 9.Other courses of work are identical with embodiment 1 with operation principle.
with reference to accompanying drawing 4: vacuum glass heat collection tube is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are divided into two groups, union elbow is passed through at fin radiator 10 two ends, the connectors such as three-way pipe are connected with flow-path tube 16, flow-path tube 16 is provided with two sections, symmetry is arranged on the both sides of air heat-collecting chamber 9, the condensation end that connects respectively the metal heat pipe 4 of correspondence position, two groups of vacuum glass heat collection tubes are arranged on the both sides of air heat-collecting chamber 9 by two sections flow-path tube 16 symmetries, two groups of vacuum glass heat collection tubes bottom is fixedly mounted on framework 1 and links into an integrated entity by framework 1 and air heat-collecting chamber 9.Be respectively equipped with a dividing plate between two flow-path tubes 16 and fin radiator 10, fin radiator 10 is arranged in the space that forms between two dividing plates, and other settings and the course of work are identical with embodiment 2.
In addition, also can be by connectors such as ring flanges, that a plurality of solar energy vacuum glass thermal-collecting tube heat pipe air heat collectors are in parallel or be together in series, form collector system, with increase heat collector to adopt hot side long-pending, more hot-airs are provided.
The above is only preferred embodiment of the present invention, is not to be the present invention to be done the restriction of other form, and any those skilled in the art may utilize the technology contents of above-mentioned announcement to be changed or be modified as the equivalent embodiment of equivalent variations.But every technical solution of the present invention content that do not break away to any simple modification, equivalent variations and remodeling that above embodiment does, still belongs to the protection domain of technical solution of the present invention according to technical spirit of the present invention.
Claims (10)
1. solar energy vacuum glass thermal-collecting tube heat pipe air heat collector, comprise a plurality of vacuum glass heat collection tubes that are arranged side by side and air heat-collecting chamber (9), air heat-collecting chamber (9) is connected as a single entity a plurality of vacuum glass heat collection tubes tops, metal heat pipe (4) is installed in vacuum glass heat collection tube, metal heat pipe (4) top is condensation end, the bottom is evaporator section, evaporator section stretches in vacuum glass heat collection tube, condensation end stretches in air heat-collecting chamber (9), be installed with thermal-arrest fin (3) on the outer ring tube wall of metal heat pipe (4) evaporator section, it is characterized in that: be provided with fin radiator (10) in described air heat-collecting chamber (9), condensation end by fin radiator (10) connection metal heat pipe (4) top, border, fin radiator (10) outside is provided with radial heat-dissipating fin of arranging (11).
2. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 1, it is characterized in that: described air heat-collecting chamber (9) comprises fin radiator (10) and the heat-dissipating fin (11) of installing in shell (18), inner bag (19), inner bag (19), be provided with heat-insulation layer (17) between shell (18) and inner bag (19), heat-dissipating fin (11) axially is radial fin radiator (10) outer ring of being distributed on along fin radiator (10) body; Shell (18) one ends are provided with air inlet (7), and the other end is provided with gas outlet (12), and air inlet (7) is located to be provided with air filter (8) and opened and closed reversing arrangement, and gas outlet (12) locate to be provided with headstock gear (13).
3. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 1 and 2, it is characterized in that: described fin radiator (10) is installed in parallel in inner bag (19), fin radiator (10) is the body of inner hollow, the body both ends are provided with plug (15), body internal circulation heat accumulation heat-conducting medium, body one end is provided with medium filler pipe (20), medium filler pipe (20) one ends stretch out air heat-collecting chamber (9) as the medium filler, and are provided with pressure relief device; Be provided with side by side a plurality of heat transfer sleeve pipes (21) in fin radiator (10), the condensation end at metal heat pipe (4) top exposes the vacuum glass heat collection tube top and inserts in heat transfer sleeve pipe (21).
4. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 3, it is characterized in that: the described vacuum glass heat collection tube that metal heat pipe (4) is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are arranged on the same side of air heat-collecting chamber (9) side by side, and the bottom of vacuum glass heat collection tube is fixedly mounted on framework (1) and goes up and pass through framework (1) and air heat-collecting chamber (9) and link into an integrated entity.
5. a kind of solar vacuum glass tube heat pipe air heat collector according to claim 3, it is characterized in that: the described vacuum glass heat collection tube that metal heat pipe (4) is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are divided into two groups, symmetry is arranged on the both sides of air heat-collecting chamber (9) side by side, and the bottom of two groups of vacuum glass heat collection tubes is fixedly mounted on framework (1) and goes up and pass through framework (1) and air heat-collecting chamber (9) and link into an integrated entity.
6. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 1 and 2, it is characterized in that: described fin radiator (10) is installed in parallel in inner bag (19), fin radiator (10) is the body of inner hollow, body two ends or side, two ends are connected by flow-path tube (16), in fin radiator (10) and flow-path tube (16) internal circulation heat accumulation heat-conducting medium, flow-path tube (16) one ends are provided with medium filler pipe (20), medium filler pipe (20) one ends stretch out air heat-collecting chamber (9) as the medium filler, and be provided with pressure relief device, be provided with side by side a plurality of heat transfer sleeve pipes (21) on flow-path tube (16), the condensation end at metal heat pipe (4) top exposes the vacuum glass heat collection tube top and inserts in heat transfer sleeve pipe (21).
7. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 6, it is characterized in that: the described vacuum glass heat collection tube that metal heat pipe (4) is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes (2) are arranged on the same side of air heat-collecting chamber (9) side by side, and the bottom of vacuum glass heat collection tube is fixedly mounted on framework (1) and goes up and pass through framework (1) and air heat-collecting chamber (9) and link into an integrated entity.
8. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 6, it is characterized in that: the described vacuum glass heat collection tube that metal heat pipe (4) is housed is arranged side by side a plurality of, a plurality of vacuum glass heat collection tubes are divided into two groups, flow-path tube (16) is arranged with two sections, two groups of vacuum glass heat collection tube symmetries are arranged on both sides, air heat-collecting chamber (9), corresponding two groups of metal heat pipes (4) by two sections flow-path tubes (16) side by side symmetry be arranged on both sides, air heat-collecting chamber (9), two groups of vacuum glass heat collection tubes bottom is fixedly mounted on framework (1) and go up and passes through framework (1) and air heat-collecting chamber (9) links into an integrated entity.
9. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 6, it is characterized in that: be horizontally disposed with dividing plate in described air heat-collecting chamber (9), dividing plate is arranged between fin radiator (10) and flow-path tube (16), dividing plate top formation air communication channel.
10. a kind of solar energy vacuum glass thermal-collecting tube heat pipe air heat collector according to claim 3, it is characterized in that: described fin radiator (10) whole longitudinal section is circular, oval, semicircle, fan-shaped, trapezoidal, rhombus or rectangle, and fin radiator (10) is one piece machine-shaping or is formed by the body outer ring that a plurality of heat-dissipating fins that are processed into separately (11) are plugged on fin radiator (10).
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CN105180474A (en) * | 2015-08-25 | 2015-12-23 | 阮静海 | Flow guide tube type energy storage device |
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CN111121188A (en) * | 2020-01-10 | 2020-05-08 | 华克医疗科技(北京)股份公司 | Radiopharmaceutical split charging hot chamber |
CN112556206A (en) * | 2020-12-05 | 2021-03-26 | 万江新能源集团有限公司 | Solar energy coupling electric energy air heating device |
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